Car wheel boring machine



Feb. 20, 1951 c. B. FAVERTY E1' Al. 2,542,318

CAR WHEEL BORING MACHINE Feb. 20, 1951 c. B. FAVERTY ET Al. 2,542,318

CAR WHEEL BORING MACHINE Filed Nov. 29, 1946 7 Sheets-Sheet 2 7 l/llllllllI/llllIIlll//l/III @CM1/Mfg Feb. 20, 1951 C. B. FAVERTY El' AL l CAR WHEEL BORING MACHINE '7 Sheets-Sheet 3 Filed Nov. 29, 1946 mlllll Feb. 20, 1951 c. B. FAVERTY Er AL.

CAR WHEEL BORING MACHINE '7 Sheets-Sheet 4 Filed Nov. 29, 1946 Feb. 20, 1951 c. B. FAVERTY ET AL. 2,542,318

CAR WHEEL BORING MACHINE Filed Nov. 29. 194e 'r sheetssnet 5` 1N lHill hmm i Feb. 20, 1951 c. a. FAVERTY Er AL.

CAR WHEEL BORING MACHINE '7 lSheets-Sheet'. 6

Filed Nov. 29, 1946 1 Willi/111111,11,lllllll/la ,g www): HUHHHH Ili Feb. 20, 1951 c. B. FAVERTY :r AL 2,542,318

CAR WHEEL BORING MACHINE- Filed Nov. 29, 1946 '7 Sheets-Sheet 7 HEAD DOWN HYoR. new HYoR. SPINDLE l" Flamme cLAMp HEAD UP m HOV PIN OUT n @gli L51 TME DELAY Ls-. m

HEDDOWN MOTOR FOREWRD Aura-mmf@ O-START PIN our--O G--STOP Pm rN--O O EMERGENCY RETURN E E C` L GLEZJEN" Y l TABLE LEFT- Q Q--cYcLE Ls-z m S- HED UP R MOTOR T U Rev. we

`Patented Feb. 20, 1.951

UNITED STATES PATENT OFFICE CAR WHEEL BORING MACHINE corporation of Delaware Application November 29, 1946, Serial No. 712,852

(Cl. 7l-4) 3 Claims.

This invention relates to new and improved car wheel boring machines and the method by which the wheels are mounted upon the machine for a boring operation and removed upon completion of the boring operation.

An important object is to speed up the wheel boring operation and increase the production of finished wheels by increasing the cutting speed and reducing the boring bar feed within the limits recommended for carbide tools.

Another object of the invention is to provide means for utilizing the high cutting speeds attainable with carbide tools and attendant reduction of feed rate consequent upon such use in the boring of car wheels.

A primary object of the invention is to provide Va car wheel boring machine in which is embodied a reciprocable table having a pair of chuck sets for holding each a wheel fixed against rotation and a rotating spindle carrying a boring bar together with means for automatically locking the table in each of the wheel boring positions and feeding the bar to the Work at a predetermined rate.

A further object of the invention consists in the means for alternately loading a Wheel on one end of a reciprocable table and unloading a wheel from the other end of the table, with means for automatically locking the table during one or the other of these operations and during the boring operation upon each of said wheels in alternating cycles.

The foregoing and other advantages are achieved by the mechanism described in the specification and illustrated in the accompanying drawings, in which Fig. 1 is a front elevational view of the car wheel boring machine of the invention assembled with loading and. unloading devices at opposite ends of the machine, and showing the table with its load of two wheels, shifted to the right and locked, one of the wheels undergoing a boring operation and the finished wheel in the process of being removed from the table by the unloading mechanism at that end and further showing a new wheel ready to be transferred from the raised platform to the table to take the place of the finished wheel;

Fig. 2 is a plan view of the same and partly in section taken on line 2--2, of Fig. 1;

Fig. 3 is a side and front elevational view of the machine showing the wheel table shifted Vto the left and locked, with the finished wheel in position to be lifted from the table and the new wheel in position beneath the boring bar ready for the boring operation;

Fig. 4 is a side elevational view of the machine with portions of the housing wall broken away to show the counterbalancing mechanism for the boring spindle housing and driving mechanism for the spindle and the solenoid operated valve means for controlling the boring bar feeding cycle;

Fig. 5 is a sectional plan view takenon line 5-5, of Fig. 6, showing the table shifting cylinders with respective pistons in the position established when the table is in its locked position at the left of the machine, as indicated in Fig. 3;

Fig. 6 is a front elevational view of the same;

Fig. 7 is a vertical sectional view taken on line 1 7, of Fig. 6, showing the table locking pin assembly with the pin entered in registered socket in the table;

Fig. 8 is a diagrammatic view ofthe wheel holding chuck assemblies on the table of the machine with mechanism for actuating the chucks separately, together with the control valves and hydraulic pump and motor assembly.

Fig. `9 is another diagrammatic View showing the control system for the mechanism for shifting the table and coordinating its movements with the feeding rate of the spindle and the locking pin actuating mechanism;

Fig. 10 is the electric power circuit for the operation of the machine and controls; and

Fig. 11 is an enlarged face view of the switch control panel |28 shown in position on the machine, as indicated in Fig. 3.

Railroad car wheels are mounted solidly upon the axle and rotate with it as a unit. The attachment of the wheel to the axle is eiected by a press-nt, the wheel being bored to smaller size than the wheel seat on the axle, causing the bore of the wheel to expand and grip the axle. It is necessary that these fits be carefully selected to insure a secure connection between the wheel and axle that will hold under the severe operating conditions of railroad service, and it is also necessary to have the bore of the Wheel concentric with the circumference of the wheel to assure smooth riding and avoid unnecessary up and down motion of the car body.

In the past, wheels have been bored on a Wheel boring machine where the wheel is carried by a rotating table and the boring bar held stationary except for the vertical feed of the bar through the bored hole. On4 that machine the wheel is held in a five-jaw chuck on a table which rotates with the wheel, the table being supported and retained in its central position by a pintle-type bearing, where the top bearing is a tapered sleeve for centering and the bottom bearing is of the 3 radial type to hold the table in alignment. With such construction the table diameter becomes quite large after allowing for chuck jaws and supports outside of a 38 diameter wheel as compared with the hole to be bored of only about 7" in diameter, and it was found impracticable to rotate this table and wheel fast enough to take advantage of the cutting speeds possible and, in some cases necessary with the better grades of tool steel and carbide tipped tools. It was apparent from our experience with carbide tipped tools on other work, that if we could increase the cutting speed and reduce the feed within the limit recommended for carbide tools, we could produce a better bore, hold size for a greater period of time without tool changes, and improve our wheel mounting practice. In the machine of our invention, as described in the specification, the wheels are held fixed during the boring operation and only the spindle rotates.

In said drawings, the present embodiment of the invention consists primarily of a car wheel boring machine comprising a base portion I3 having rails II extending longitudinally thereof, upon which is slidably mounted a reciprocat'ng table I2 equipped with two sets of chuck asseme blies I3 operable independently of each other and movable with the table from one end of the machine to the other for a purpose hereinafter to be described. The table is supported upon rails I I held in position on base I by keys I4 and entered in grooves I6 in the underside of the table, as best shown in Fig. 4 As indicated, the grooves on Ways I6 are V-shaped and of generous proportions to center the table and retain it in centered position along the longitudinal center line of the bed I0 to compensate for the wear in service of both rails II and lthe grooves I5. Extend-y ing rearwardly of the bed section I3 of the machine is a housing portion 26 rising upwardly from its base ZI to a height sufficient to accommodate counterbalancing mechanism 25 for the boring mill housing 26 slidable vertically in the fore part 2l of such housing portion 20 overly-v ing the reciprocating table I2. Housing 20 further contains motor 28 supported .at the roof of said housing by bracket 29 and with its armature shaft 3i) directly connected with a fluid pump 3! immersed in the body of oil 32 held in tank 33 for supplying hydraulic power to the boring mill housing actuating cylinders 34 and 35 through conduits 375-31 diagrammatically indicated in Fig. 9.

As shown in Fig. 4, a counterbalancing mechanism 25 comprising the counterweight portion 40 is movable vertically in guide angles 4I disposed as shown in Fig, 2, and supported by means of .a supporting rod 42 suspended from sprocket chain 43 meshing with an idler sprocket wheel 44 and the underside of a second sprocket wheel 45 journaled in bearings 46 secured to the boring mill housing 26 and anchored at its end to the roof of housing 23 by bolt 4l, whereby a minimum of effort will be required to actuate the boring mill housing 25 up and down with its contained load of the boring bar 48, the spindle 49 rotatably supporting saidboring bar, the variable transmission mechanism in casing U and mechanism actuating motor 5I superposed on said housing 25 for rotatably driving the spindle 49, eifected in this embodiment by means of the belt coupling 52 indicated in this figure, though obviously such couplingmay be by direct connection between said transmission and motor. The use Vof variabletransmission mechanism is de- 4 signed to drive the spindle 49 at cutting speeds controlled by shaft levers 53 and 54 on the face of the spindle housing 26, connected with rods 59 extending upwardly to the gear casing 50, for the purpose .of meshing the gears properly for the speeds desired out of the four available by the operation of these levers. The speeds are selected to accommodate them to the boring of cast iron or steel wheels and for tough or soft materials. As shown in Figs. l, 3 and 4, the boring bar 48 is equipped with a lower roughing cutter 55, an upper chamfering cutter 56 for boring a starting taper 5l as the last step in the sequence of boring operations on a wheel, and a bore finishing cutter 58 positioned at an intermediate point on .the boring bar 48, as shown in Fig. 3. The means for controlling the sequence of these different cutting phases of the boring operation is embodied in the movement downwardly of the boring bar 48 during which the roughing cutter rst engages the wheel, followed closely by the bore finishing cutter 58, vafter which the nal chamfering operation is performed by cutter 56 to form the bore taper 51 to facilitate pressing the finished wheel upon the axle as before explained. As indicated in Fig. 9, the controls are set to feed the boring bar and spindle downwardly to the work rapidly until the boring position shown in Fig. 4 is reached, when the downward travel is slowed down to the predetermined feeding rate followed by a slight dwell when the motor circuit shown in Fig. 1D is nterrupted to permit boring bar and spindle to recede to their normal upper position of rest as indicated in Fig. 3, under the impetus of operating cylinders 34l and 35 shown in Figs. .1, 3, 4 and 9, This boring bar feed mechanism is .interlocked with mechanism for shifting and locking the table I2 to prevent the starting of the boring operation until the table is properly locked in place in either of lthe positions shown in Figs. l and 3.

The table I2, mounted as described, is shiftable with its load of two wheels 63 and 5I, one of which, 6I, has been finished and ready to be unloaded by the loading and unloading mechanism i installed at the right hand end of the boring mill as depicted in'Fig. l, and the other wheel, 63, in that figure, undergoing a boring operation with the boring bar 4B in its lowermost position with chamfcring cutter 55 operatively engaging the wheel. During the boring operation on wheel 6&3, the finished wheel 3l is lifted ofi the table by the tongs 62 of the unloading mechanism I and a new wheel 53 deposited on said table by the lifting tongs 64 actuated in a manner presently to be described. With new wheel 53 in position and boring of wheel 6D completed, the table I2 is released by withdrawal of locking pin 35 from registered socket 66, by mechanism shown in Figs. l, 5 through '7, and 9, operable automatically upon lifting of the spindle-49 and boring `bar 48, and automatically shifted with its load of finished Wheel Gil and new wheel 53 toward the position shown in Fig. 3, wherein the finished wheel 63 is brought into position to be lifted off the table by the loading and unloading mechanism 2 installed at the Lft hand end of the machine while the wheel S3 is in centered position for the boring operation with the boring bar 43 ready to be lowered into engagement with said wheel automatically upon upward thrust of locking pin S5 into registered socket 55 lby mechanism indicated in Figs. 3 5 through 7, and 9, whereupon tongs 3l of unloading mechanism 2 will remove wheel 69 from the table I2 and a new' Wheel es deposited upon' the'tabie by the v companion lifting tongs 59, during which time the boring operation upon wheel 63 may be carried to completion.

The operatingV mechanism for shuttling the table I2 between the loading and unloading installations I and 2 at opposite sides of the machinel and the coordinating mechanisms `for looking and unlocking the table automatically and in timed relationship with up and down movements of the boringbar spindle housing shown diagrammatically in Figf9, all derive their power from oil under pressure delivered by uid 'pump 3|` driven continuously by motor 2B. The table is power actuated by hydraulic cylinders *lil and lil, disposedas graphically illustrated in Fig.- 9, and on opposite sides of the bed I as indicated in Figs. 2 and 4, one actuates the table in one direction and the other shifts the table tothe limit of movement in the opposite direction. As shown in Figs. 1 through 4, the

Wheels to be operated upon are placed upon the i .chuck assemblies i3 tted to the table I2 in xed relationship with each other and the table and equipped with sets of E-jaw chucks 'I5 itil formed with cam slots 3| and d2 arranged to 1 open and close the chuck jaws movable in guides it. The jaws I5 are operated independently of all other functions of the machine and the chucks of each assembly lI3 are operable independently of each other as a safety measure. The chuck assemblies are hydraulically driven by iluid pump 90 and motor 9| housed in the has@ it of the machine and shown diagram- Vmatically in Fig. 8 with circuits 92 and 93 extending to respective Li-way valves 94| and 95 manually operable by control handles 96 and 9?, respectively. The valves are interlocked to prevent the opening of the chucks of the two assemblies i3 simultaneously but arranged to permit the chucks to be closed either individually or together. i

l' When the table shift control is actuated, the table I3 shifts to place a wheel under the boring bar' i9 through the medium of the fluid delivered lfrom pump 3l to 4-way valve 98 which controls the movement of the locking pin |55. As best shown in Figs. 5, 6, 'l and 9, the pin is lifted into registered sockete through wedging action of inclined plane on block 99 under thrust of piston 'S3 actuated from hydraulic cylinder 84, and pin is withdrawn from socket 95 by wedging action of inclined plane on block 99 under thrust of piston 85 in cylinder 86. The pin actuating mechanism described is interlocked with the bar feed control-in a manner to prohibit the starting of the feed until the table I2 has been properly locked in place. When the locking pin has been raised through action of pressure cylinder 8f3 requiring pressure in line S'I, this pressure would be carried through line di! to the bottom side of sequence valve S9 which then would be forced to its closed position, allowing pressure to be built up in` either of the lines that actuate the table through cylinders I9 and VI, hydraulic pressure being carried directly through li-way valve 98, through line |06, to dway solenoid operated valve |0|. Manifestly, if valve lill is in position to deliver iiuid pressure to line |82, and sequence valve 89 is in closed position, fluid pressure will be carried through 6. check valve |031 and orince |04 to line |05 and to cylinder 10, the table I2, under thrust of piston |96 against abutment l'l on the table, would be shifted to the right as viewed in Figs.. 1, 2 and 9, and if valve |0| is in position to deliver iluid to line It, iiuid pressure will be carried through check valve 99 and oriiice to cylinder '|I, the table, under thrust of piston HI against abutment It'I on the table would be shifted in the opposite direction. As the table approaches the end of its travel in either direction. of movement,fthe`check valve H33 is closed mechanically by wedge action as best shown in Fig. 3, when table moves to the left in this figure, or when check valve It is closed by wedge action when table moves in reverse direction to the right as shown in Figs. 1 and 9, all of the pressure fluid is caused to now through restrictive orice |04 or H0 to greatly slow the travel of the table to act as a cushion against shock at the end of the stroke.

After the table has reached a position at the end of its travel, electric switches |l2 or ||3 will be contacted by points Elfi or H5, operating to energize the solenoid that shifts the ll-way valve 98 to allow fluid pressure to flow into line IG and cylinder 86 which engages the lock pin in the table. In locked position, the pin |55 closes switches Il and I I8 that are interconnected with the motor starting circuit through a solenoid operated relay. Fluid pressure is carried through solenoid operated 4-way valve |0l, through line |20, to control station |2I. The motor, having been energized, quickly picks up speed and, at the same time,` uid pressure is carried through control station |2| to the top of cylinders 3d and 35 through lines |22 and |23, whereby the boring bar i8 is fed down to the work. When the bar has reached the boring position, its downward travel is retarded to the proper feeding rate, and it continues on through the work until the feeding cycle is interrupted by the opening of switch |24 shown in Fig. 9, whereupon the solenoid operated valve at control station I2| is acl, tuated to interrupt the motor circuit and return the boring bar assembly to its upper position throughuid pressure carried to the bottom of cylinders 34 and 35 through lines |25 and |26. The solenoid operated valve at control station I2! is so constructed as to provide a dwell at the end of the feeding cycle before the cylinders are restored to starting condition indicated in this figure to complete the boring cycle. Upon completion of this cycle, the operator presses 'the cycle button |2'I on the control panel |28 shown in Fig. 3, which energizes the solenoid operating valve 98 to withdraw locking pin 55 from registering socket 66 to unlock table I2 through line Il@ to cylinder 86 as shown in Fig. 9. When piston 85 has completed its travel, switch II'! is closed to energize solenoids operating the valve |0| to shift the table to the new working position and closing switches H2 or ||3 which, in turn, will energize the solenoid operating the valve 93 to cause the locking pin G5 to again enter a registering socket 6B to lock the table, at which time, the switch IS is contacted, which again starts the driving motor 5|. The contact switches which control the position of the boring cycle are shown at |20.' and l i 9 in Figs. 4 and 9 and controlled during up and down movement of the spindle housing 25 by means of actuating blocks |30 slidably positioned on rod |29 attached to spindle housing 29 and moving with it, whereby the position of the blocks |30 traveling with the rod and housing actuates 7` the switches |24 and VI IB at 'predetermined positions and in proper sequence. The spindle housing 2S, it will be noted, Within which the spindle 49 rotates, is itself `movable vertically between guides 24 secured to the face of the machine, as best shown in Figs. l through 4.

The electric power. required for the operation of the machine and controls, is derived from three incoming powerlines i3 as shown in Fig. 1Q, .and indicating 3-phase source of power at 44() volts and 60 cycles. These electric circuits are carried through the proper starting switches to the two motors .2S and 9| for driving the fluid pumps 3| and 9i), respectively, and to the motor 5|.foi' driving the spindle `t9 through the starting switches on panel i223. This motor drive I is provided with .a reversing switch for so-called plugging of the motor to ,quickly stop the rotation of Athe entire mechanism at the end of the operating stroke. In Fig. lil, the power lines are shown extending to solenoids of valves 98, Il and |2|, and these solenoids are energized in their proper sequence through the switches shown in this figure. Power is also taken from the incoming circuit to energize the transformer ITI, indicated in this figure, for the purpose of reducing the voltage to a safe amount for the push button and other control circuits. f

To start the machine, the start switch designated inthe circuit of Fig. 10, energzes the motors 28 and .9i to drive hydraulic pumps 3| and 90, respectively, and when operating pressure has become established, switch H will close to energize all the switches controlled from panel |23, shown in Fig. ll.. The selector switch is either turned to manual contro or automatic control and as indicated in the upper left hand corner of the panel, the switch is indicated with the automatic control circuit closed. To start the cycle, the cycle button at lower right hand of the panel is pushed. The locking pin 65 is in and switch LS-i (IIB) is closed and solenoid S-B will be energized momentarily which will Vshift the Ll-way valve 98, and the locking pin 65 4will be forced out of its socket 6.6 which closes switch IIS-5 (I Il). The table I2 is either in the right or left hand position and either switch 11S-3 (I I3) or LS-Li I2) is closed. Assume LS-B (I I3), current will not be carried to S- at valve 9S which operates the locking pin in because of the time delay switch which must close before the pin in circuit is completed but will be car-- ried through S-5 :at ll-way valve iBI to shift the table i2 to the right. As soon as the table starts to shift, both switches LS-B (I I3) and LSB- 4 (I I2) will be opened and will stop `the pin in operation as this opens the time delay until the table shift is complete and the switch LS-li (H2) is closed and the time delay coil is again energized. An interlock switch is provided which will prevent the table shift cycle repeating :before switch LS-S (Htl) has been energized and the cycle button on panel |23, pushed again.

As soon as the locking pin 65 is in and swi-tch LS- (IES) closed, the mot/or circuit will be closed along with the down feed through switch S-i, at valve l2i, providing switch LS-I (H9) is closed, which means that the head Vrnust start from the up position and the table be shifted with either switch LS-S (I I3) or LS- (M2) closed. The motorcontrol circuit is also provided with a mechanical interlock which is released by the closing of switch LS-5 (i I'I) or the pin out position to assure :this operation be performed in the proper sequence and `to prevent 8 the head down operation from 'Te-Cycling.; Closing of switch LS2 (|24) at the end of the down stroke through the time delay provides the dwell at the end of the stroke before the motorisreversed or plugged and switch S--2, at valve |2|., energized, which returns the head to the upper or starting position. The pin inf pin out, table right" and table left operations can bev accomplished manually, if necessaryJ in the event of failure of any of the automatic circuits, as willbe obvious.

From the foregoing descriptionof the car wheel boring machine of this invention, it lwill be noted that although the disclosure proceeds upon-.the assumption that the use of three cutters 55, 56 and 58 is desirable, it may be `found practicable to dispense with one or the other of cutters 55 and 58, the machine having been designed so .that but one of such cutters can be used to complete the bore to size in one pass. The rigid frame construction, the large spindle diameter., the flanged stub bar 48 with a minimum of unsupported length, andthe carbide tipped tools with a low rate of wear, are all proportioned, processed and assembled to withstand the weight and speed of handling of the materials to be worked upon. Y

The safety of operation of the whole machine and the precision of the control system described and its simplicity render `possible the expeditious handling of the product at a minimum-of expense. Ehe loading and unloading installations I and 2, depicted in Figs. 1 and 2 disposed at opposite sides of the machine, are in accordance lwith the mechanism covered in Patent 1,541,527 of 6-9-25 to Gemert Powell, and found to lend themselves eommendably to the system of operation incident to the operation of the reciprocab'le table wherein awheel is deposited upon the table at one end of the machine and carried by the table `to the boringposition, during which operation another wheel is vdeposited. upon the table at ythe opposite end of the machine, then upon completion of the boring operation on the 'lrst wheel deposited, the table will be shifted in the reverse direction to bring the second wheel deposited to the boring position, and the finished wheel is then removed and another wheel deposited -on thetable to take its place, so that upon completion of the boring operation on the other wheel at the other end of the table, the table will again be shifted to Apermit removal of that wheel from the table and the loading of another wheel from the stock pile at that side of the machine, all as depicted in Figs. 1, 2 and 3, and previously outlined.

The loading and unloading installations I and 2 comprise each the transferring tong mechanism i453 having a supporting standard |4| slidably and rotatably mounted in the cylinder |42 secured to the floor |43 of the shop and operatively connectedv with a hydraulic or compressed air pressure system beneath the floor (not shown) and effective upon operation of the valve |44 to raise or lower the standard |4| to bring the transferring mechanism vInti) into position to deposit work on the clutch assemblies carried by the table or to remove it after a boring operation and controlled by lever |45 operatively connecting respective lifting tong members |52V andV 54 and 67 and 69. The installations further comprise the wheel hoisting platform VMI5 upon which a wheel from the stock pile may lloe rolled preparatory to elevating the same and from Awhich a finished wheel may be rolled :upon lowering of the platform. The raising and lowering of the platform ills is eoected by means of supporting standard Ml slidably mounted in cylinier ldd also se cured to the shop iioor ld@ and connected to the pressure system beiore referred to, and opively controlled by valve pedal 49.

To effect automatic tilting or platform M6 the horizontal raised position to a lower tilted position at the door line, the platform is pivotally `secured to supporting standard dl at The platform is tilted during the raising lowering operation by link l! pivotally anchored to the floor and secured at its upper end to the platform by pin i52 whereby the downward movement of the supporting standard ill'l will cause the link to function as a strut to hold the edge of the platform raised with respect to the lowered portion of the platform at pivot E59, in which position or the platform, a completed Wheel may be removed from it and another one mounted in its place, as indicated at the left of Figs. l and 2.

What is claimed is:

l. In car wheel boring mill inmallation including loading and unloading means for alternately delivering and removing worlr to and from the boring mill at its opposite a wheel boring machine comprising a portion having rails extending longitudinally thereof, a table slidably mounted upon said rails having two sets of chuck assemblies operable independently of each other adapted each to retin a car wheel to be bored and reciprocable with the table between said loading and unloading means, an upright housing section extending rearwardly of the base portion and rising substantially above level of the table centrally of said machine, a boring mill housing assembly extending above the level of the upright housing' section in overlying relan ticnship to said table and slidably mounted in the face of said housing section for vertical reciprocation toward and away from the work on the table, a boring-bar spindle supported for rotation in said housing assembly, a driving motor mounted on the housing assembly above said housing section, a driving' connection between the motor and said boring-bar spindle including multi-speed mechanism operatively engaging said spindle and carried by said housing assembly, hydraulic cylinder mechanism for raising and lowering said housing assembly, means on the housing assembly for controlling said multi-speed mechanism.

2. A car wheel boring machine comprising a base portion having rails extending longitudinally thereof, a reciprocating table slidably mounted upon said rails and having two sets of chuck assemblies operable independently of each other and movable With the table from one end of said base portion to the other adapted each to retain a car wheel to be bored, an upright housing section extending rearwardly of the base portion and rising substantially above the level of said table centrally or" the machine, a boring rnill housing assembly slidable vertically in guides on the face of said upright housing section overlying said reciprocating table and extending above the level of the housing section and including a boringmbar spindle rotatably mounted in the boring mill housing, a driving motor mounted on the boring mill housing above said upright housing section, a driving connection between said motor and boring-bar spindle including multispeed mechanism carried by the boring mill housing and means on the housing for controlling said mechanism, mechanism in said upright housing section counterbalancing the vertical reciprocations of said boring mill housing assembly, hydraulic means for actuating said reciprocating table alternately to locate one of said chuck assemblies and contained wheel beneath said boring-bar spindle, hydraulic means for raising and lowering said boring mill housing assembly between an upper position of rest and a lower operative position 'for boring said wheel, and hydraulic power supply means for both said hydraulic means mounted in said housing section.

3. A car wheel boring machine comprising a base portion, a reciprocating table slidably mounted on said base portion and having two sets of chuck assemblies operable independently of each other adapted each to contain a car wheel to be bored and movable with the table from one end of said base portion to the other, an upright housing section associated with the base portion centrally of the machine and rising above the level of said table, a boring mill housing assembly slidable vertically on the face of said upright housing section overlying said reciprocating table and including a boring-bar spindle rotatably mounted in the housing, a driving motor for the spindle carried by said housing assembly, multi-speed gear mechanism between the driving motor and said spindle, control means on the housing assembly for selectively engaging the gear mechanism to adjust the rotative speed of said spindle, hydraulic means for actuating said reciprocating table alternately to locate one of said chuck assemblies and contained wheel beneath said boring-bar spindle, hydraulic means for raising and lowering said boring mill housing assembly between an upper retracted position and a lower operative position for boring said wheel, and hydraulic power supply means for both said hydraulic means.

CLYDE B. FAVERTY. ARTHUR H. HARTWIG. WILLIAM J. MCDONALD. LOUIS WULFF.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Number Name Date 497,738 Wood May 16, 1893 1,392,304 Davis Oct, 4, 1921 1,433,818 Hill Oct. 31, 1922 1,541,527 Powell June 9, 1925 1,649,411 Kaseberg Nov. 15, 1927 2,019,814 Holmes et al Nov. 5, 1935 2,195,861 Hunt Apr. 2, 1940 2,395,518 Svenson Feb. 2:6, 1946 OTHER REFERENCES Krause Catalog, Feinbohren, page 7, Feb. 4, 1937. (Copy on le in Div. 68, class 77.) 

